-/***************************************************************************
-
- Atari Jaguar hardware
-
-****************************************************************************
-
- ------------------------------------------------------------
- JERRY REGISTERS
- ------------------------------------------------------------
- F10000-F13FFF R/W xxxxxxxx xxxxxxxx Jerry
- F10000 W xxxxxxxx xxxxxxxx JPIT1 - timer 1 pre-scaler
- F10004 W xxxxxxxx xxxxxxxx JPIT2 - timer 1 divider
- F10008 W xxxxxxxx xxxxxxxx JPIT3 - timer 2 pre-scaler
- F1000C W xxxxxxxx xxxxxxxx JPIT4 - timer 2 divider
- F10010 W ------xx xxxxxxxx CLK1 - processor clock divider
- F10012 W ------xx xxxxxxxx CLK2 - video clock divider
- F10014 W -------- --xxxxxx CLK3 - chroma clock divider
- F10020 R/W ---xxxxx ---xxxxx JINTCTRL - interrupt control register
- W ---x---- -------- (J_SYNCLR - clear synchronous serial intf ints)
- W ----x--- -------- (J_ASYNCLR - clear asynchronous serial intf ints)
- W -----x-- -------- (J_TIM2CLR - clear timer 2 [tempo] interrupts)
- W ------x- -------- (J_TIM1CLR - clear timer 1 [sample] interrupts)
- W -------x -------- (J_EXTCLR - clear external interrupts)
- R/W -------- ---x---- (J_SYNENA - enable synchronous serial intf ints)
- R/W -------- ----x--- (J_ASYNENA - enable asynchronous serial intf ints)
- R/W -------- -----x-- (J_TIM2ENA - enable timer 2 [tempo] interrupts)
- R/W -------- ------x- (J_TIM1ENA - enable timer 1 [sample] interrupts)
- R/W -------- -------x (J_EXTENA - enable external interrupts)
- F10030 R/W -------- xxxxxxxx ASIDATA - asynchronous serial data
- F10032 W -x------ -xxxxxxx ASICTRL - asynchronous serial control
- W -x------ -------- (TXBRK - transmit break)
- W -------- -x------ (CLRERR - clear error)
- W -------- --x----- (RINTEN - enable receiver interrupts)
- W -------- ---x---- (TINTEN - enable transmitter interrupts)
- W -------- ----x--- (RXIPOL - receiver input polarity)
- W -------- -----x-- (TXOPOL - transmitter output polarity)
- W -------- ------x- (PAREN - parity enable)
- W -------- -------x (ODD - odd parity select)
- F10032 R xxx-xxxx x-xxxxxx ASISTAT - asynchronous serial status
- R x------- -------- (ERROR - OR of PE,FE,OE)
- R -x------ -------- (TXBRK - transmit break)
- R --x----- -------- (SERIN - serial input)
- R ----x--- -------- (OE - overrun error)
- R -----x-- -------- (FE - framing error)
- R ------x- -------- (PE - parity error)
- R -------x -------- (TBE - transmit buffer empty)
- R -------- x------- (RBF - receive buffer full)
- R -------- ---x---- (TINTEN - enable transmitter interrupts)
- R -------- ----x--- (RXIPOL - receiver input polarity)
- R -------- -----x-- (TXOPOL - transmitter output polarity)
- R -------- ------x- (PAREN - parity enable)
- R -------- -------x (ODD - odd parity)
- F10034 R/W xxxxxxxx xxxxxxxx ASICLK - asynchronous serial interface clock
- ------------------------------------------------------------
- F14000-F17FFF R/W xxxxxxxx xxxxxxxx Joysticks and GPIO0-5
- F14000 R xxxxxxxx xxxxxxxx JOYSTICK - read joystick state
- F14000 W x------- xxxxxxxx JOYSTICK - latch joystick output
- W x------- -------- (enable joystick outputs)
- W -------- xxxxxxxx (joystick output data)
- F14002 R xxxxxxxx xxxxxxxx JOYBUTS - button register
- F14800-F14FFF R/W xxxxxxxx xxxxxxxx GPI00 - reserved
- F15000-F15FFF R/W xxxxxxxx xxxxxxxx GPI01 - reserved
- F16000-F16FFF R/W xxxxxxxx xxxxxxxx GPI02 - reserved
- F17000-F177FF R/W xxxxxxxx xxxxxxxx GPI03 - reserved
- F17800-F17BFF R/W xxxxxxxx xxxxxxxx GPI04 - reserved
- F17C00-F17FFF R/W xxxxxxxx xxxxxxxx GPI05 - reserved
- ------------------------------------------------------------
- F18000-F1FFFF R/W xxxxxxxx xxxxxxxx Jerry DSP
- F1A100 R/W xxxxxxxx xxxxxxxx D_FLAGS - DSP flags register
- R/W x------- -------- (DMAEN - DMA enable)
- R/W -x------ -------- (REGPAGE - register page)
- W --x----- -------- (D_EXT0CLR - clear external interrupt 0)
- W ---x---- -------- (D_TIM2CLR - clear timer 2 interrupt)
- W ----x--- -------- (D_TIM1CLR - clear timer 1 interrupt)
- W -----x-- -------- (D_I2SCLR - clear I2S interrupt)
- W ------x- -------- (D_CPUCLR - clear CPU interrupt)
- R/W -------x -------- (D_EXT0ENA - enable external interrupt 0)
- R/W -------- x------- (D_TIM2ENA - enable timer 2 interrupt)
- R/W -------- -x------ (D_TIM1ENA - enable timer 1 interrupt)
- R/W -------- --x----- (D_I2SENA - enable I2S interrupt)
- R/W -------- ---x---- (D_CPUENA - enable CPU interrupt)
- R/W -------- ----x--- (IMASK - interrupt mask)
- R/W -------- -----x-- (NEGA_FLAG - ALU negative)
- R/W -------- ------x- (CARRY_FLAG - ALU carry)
- R/W -------- -------x (ZERO_FLAG - ALU zero)
- F1A102 R/W -------- ------xx D_FLAGS - upper DSP flags
- R/W -------- ------x- (D_EXT1ENA - enable external interrupt 1)
- R/W -------- -------x (D_EXT1CLR - clear external interrupt 1)
- F1A104 W -------- ----xxxx D_MTXC - matrix control register
- W -------- ----x--- (MATCOL - column/row major)
- W -------- -----xxx (MATRIX3-15 - matrix width)
- F1A108 W ----xxxx xxxxxx-- D_MTXA - matrix address register
- F1A10C W -------- -----x-x D_END - data organization register
- W -------- -----x-- (BIG_INST - big endian instruction fetch)
- W -------- -------x (BIG_IO - big endian I/O)
- F1A110 R/W xxxxxxxx xxxxxxxx D_PC - DSP program counter
- F1A114 R/W xxxxxxxx xx-xxxxx D_CTRL - DSP control/status register
- R xxxx---- -------- (VERSION - DSP version code)
- R/W ----x--- -------- (BUS_HOG - hog the bus!)
- R/W -----x-- -------- (D_EXT0LAT - external interrupt 0 latch)
- R/W ------x- -------- (D_TIM2LAT - timer 2 interrupt latch)
- R/W -------x -------- (D_TIM1LAT - timer 1 interrupt latch)
- R/W -------- x------- (D_I2SLAT - I2S interrupt latch)
- R/W -------- -x------ (D_CPULAT - CPU interrupt latch)
- R/W -------- ---x---- (SINGLE_GO - single step one instruction)
- R/W -------- ----x--- (SINGLE_STEP - single step mode)
- R/W -------- -----x-- (FORCEINT0 - cause interrupt 0 on GPU)
- R/W -------- ------x- (CPUINT - send GPU interrupt to CPU)
- R/W -------- -------x (DSPGO - enable DSP execution)
- F1A116 R/W -------- -------x D_CTRL - upper DSP control/status register
- R/W -------- -------x (D_EXT1LAT - external interrupt 1 latch)
- F1A118-F1A11B W xxxxxxxx xxxxxxxx D_MOD - modulo instruction mask
- F1A11C-F1A11F R xxxxxxxx xxxxxxxx D_REMAIN - divide unit remainder
- F1A11C W -------- -------x D_DIVCTRL - divide unit control
- W -------- -------x (DIV_OFFSET - 1=16.16 divide, 0=32-bit divide)
- F1A120-F1A123 R xxxxxxxx xxxxxxxx D_MACHI - multiply & accumulate high bits
- F1A148 W xxxxxxxx xxxxxxxx R_DAC - right transmit data
- F1A14C W xxxxxxxx xxxxxxxx L_DAC - left transmit data
- F1A150 W -------- xxxxxxxx SCLK - serial clock frequency
- F1A150 R -------- ------xx SSTAT
- R -------- ------x- (left - no description)
- R -------- -------x (WS - word strobe status)
- F1A154 W -------- --xxxx-x SMODE - serial mode
- W -------- --x----- (EVERYWORD - interrupt on MSB of every word)
- W -------- ---x---- (FALLING - interrupt on falling edge)
- W -------- ----x--- (RISING - interrupt of rising edge)
- W -------- -----x-- (WSEN - enable word strobes)
- W -------- -------x (INTERNAL - enables serial clock)
- ------------------------------------------------------------
- F1B000-F1CFFF R/W xxxxxxxx xxxxxxxx Local DSP RAM
- ------------------------------------------------------------
- F1D000 R xxxxxxxx xxxxxxxx ROM_TRI - triangle wave
- F1D200 R xxxxxxxx xxxxxxxx ROM_SINE - full sine wave
- F1D400 R xxxxxxxx xxxxxxxx ROM_AMSINE - amplitude modulated sine wave
- F1D600 R xxxxxxxx xxxxxxxx ROM_12W - sine wave and second order harmonic
- F1D800 R xxxxxxxx xxxxxxxx ROM_CHIRP16 - chirp
- F1DA00 R xxxxxxxx xxxxxxxx ROM_NTRI - traingle wave with noise
- F1DC00 R xxxxxxxx xxxxxxxx ROM_DELTA - spike
- F1DE00 R xxxxxxxx xxxxxxxx ROM_NOISE - white noise
- ------------------------------------------------------------
- F20000-FFFFFF R xxxxxxxx xxxxxxxx Bootstrap ROM
-
-****************************************************************************/
+//
+// JERRY Core
+//
+// by cal2
+// GCC/SDL port by Niels Wagenaar (Linux/WIN32) and Caz (BeOS)
+// Cleanups by James L. Hammons
+//
+// ------------------------------------------------------------
+// JERRY REGISTERS (Mapped by Aaron Giles)
+// ------------------------------------------------------------
+// F10000-F13FFF R/W xxxxxxxx xxxxxxxx Jerry
+// F10000 W xxxxxxxx xxxxxxxx JPIT1 - timer 1 pre-scaler
+// F10004 W xxxxxxxx xxxxxxxx JPIT2 - timer 1 divider
+// F10008 W xxxxxxxx xxxxxxxx JPIT3 - timer 2 pre-scaler
+// F1000C W xxxxxxxx xxxxxxxx JPIT4 - timer 2 divider
+// F10010 W ------xx xxxxxxxx CLK1 - processor clock divider
+// F10012 W ------xx xxxxxxxx CLK2 - video clock divider
+// F10014 W -------- --xxxxxx CLK3 - chroma clock divider
+// F10020 R/W ---xxxxx ---xxxxx JINTCTRL - interrupt control register
+// W ---x---- -------- (J_SYNCLR - clear synchronous serial intf ints)
+// W ----x--- -------- (J_ASYNCLR - clear asynchronous serial intf ints)
+// W -----x-- -------- (J_TIM2CLR - clear timer 2 [tempo] interrupts)
+// W ------x- -------- (J_TIM1CLR - clear timer 1 [sample] interrupts)
+// W -------x -------- (J_EXTCLR - clear external interrupts)
+// R/W -------- ---x---- (J_SYNENA - enable synchronous serial intf ints)
+// R/W -------- ----x--- (J_ASYNENA - enable asynchronous serial intf ints)
+// R/W -------- -----x-- (J_TIM2ENA - enable timer 2 [tempo] interrupts)
+// R/W -------- ------x- (J_TIM1ENA - enable timer 1 [sample] interrupts)
+// R/W -------- -------x (J_EXTENA - enable external interrupts)
+// F10030 R/W -------- xxxxxxxx ASIDATA - asynchronous serial data
+// F10032 W -x------ -xxxxxxx ASICTRL - asynchronous serial control
+// W -x------ -------- (TXBRK - transmit break)
+// W -------- -x------ (CLRERR - clear error)
+// W -------- --x----- (RINTEN - enable receiver interrupts)
+// W -------- ---x---- (TINTEN - enable transmitter interrupts)
+// W -------- ----x--- (RXIPOL - receiver input polarity)
+// W -------- -----x-- (TXOPOL - transmitter output polarity)
+// W -------- ------x- (PAREN - parity enable)
+// W -------- -------x (ODD - odd parity select)
+// F10032 R xxx-xxxx x-xxxxxx ASISTAT - asynchronous serial status
+// R x------- -------- (ERROR - OR of PE,FE,OE)
+// R -x------ -------- (TXBRK - transmit break)
+// R --x----- -------- (SERIN - serial input)
+// R ----x--- -------- (OE - overrun error)
+// R -----x-- -------- (FE - framing error)
+// R ------x- -------- (PE - parity error)
+// R -------x -------- (TBE - transmit buffer empty)
+// R -------- x------- (RBF - receive buffer full)
+// R -------- ---x---- (TINTEN - enable transmitter interrupts)
+// R -------- ----x--- (RXIPOL - receiver input polarity)
+// R -------- -----x-- (TXOPOL - transmitter output polarity)
+// R -------- ------x- (PAREN - parity enable)
+// R -------- -------x (ODD - odd parity)
+// F10034 R/W xxxxxxxx xxxxxxxx ASICLK - asynchronous serial interface clock
+// ------------------------------------------------------------
+// F14000-F17FFF R/W xxxxxxxx xxxxxxxx Joysticks and GPIO0-5
+// F14000 R xxxxxxxx xxxxxxxx JOYSTICK - read joystick state
+// F14000 W x------- xxxxxxxx JOYSTICK - latch joystick output
+// W x------- -------- (enable joystick outputs)
+// W -------- xxxxxxxx (joystick output data)
+// F14002 R xxxxxxxx xxxxxxxx JOYBUTS - button register
+// F14800-F14FFF R/W xxxxxxxx xxxxxxxx GPI00 - reserved
+// F15000-F15FFF R/W xxxxxxxx xxxxxxxx GPI01 - reserved
+// F16000-F16FFF R/W xxxxxxxx xxxxxxxx GPI02 - reserved
+// F17000-F177FF R/W xxxxxxxx xxxxxxxx GPI03 - reserved
+// F17800-F17BFF R/W xxxxxxxx xxxxxxxx GPI04 - reserved
+// F17C00-F17FFF R/W xxxxxxxx xxxxxxxx GPI05 - reserved
+// ------------------------------------------------------------
+// F18000-F1FFFF R/W xxxxxxxx xxxxxxxx Jerry DSP
+// F1A100 R/W xxxxxxxx xxxxxxxx D_FLAGS - DSP flags register
+// R/W x------- -------- (DMAEN - DMA enable)
+// R/W -x------ -------- (REGPAGE - register page)
+// W --x----- -------- (D_EXT0CLR - clear external interrupt 0)
+// W ---x---- -------- (D_TIM2CLR - clear timer 2 interrupt)
+// W ----x--- -------- (D_TIM1CLR - clear timer 1 interrupt)
+// W -----x-- -------- (D_I2SCLR - clear I2S interrupt)
+// W ------x- -------- (D_CPUCLR - clear CPU interrupt)
+// R/W -------x -------- (D_EXT0ENA - enable external interrupt 0)
+// R/W -------- x------- (D_TIM2ENA - enable timer 2 interrupt)
+// R/W -------- -x------ (D_TIM1ENA - enable timer 1 interrupt)
+// R/W -------- --x----- (D_I2SENA - enable I2S interrupt)
+// R/W -------- ---x---- (D_CPUENA - enable CPU interrupt)
+// R/W -------- ----x--- (IMASK - interrupt mask)
+// R/W -------- -----x-- (NEGA_FLAG - ALU negative)
+// R/W -------- ------x- (CARRY_FLAG - ALU carry)
+// R/W -------- -------x (ZERO_FLAG - ALU zero)
+// F1A102 R/W -------- ------xx D_FLAGS - upper DSP flags
+// R/W -------- ------x- (D_EXT1ENA - enable external interrupt 1)
+// R/W -------- -------x (D_EXT1CLR - clear external interrupt 1)
+// F1A104 W -------- ----xxxx D_MTXC - matrix control register
+// W -------- ----x--- (MATCOL - column/row major)
+// W -------- -----xxx (MATRIX3-15 - matrix width)
+// F1A108 W ----xxxx xxxxxx-- D_MTXA - matrix address register
+// F1A10C W -------- -----x-x D_END - data organization register
+// W -------- -----x-- (BIG_INST - big endian instruction fetch)
+// W -------- -------x (BIG_IO - big endian I/O)
+// F1A110 R/W xxxxxxxx xxxxxxxx D_PC - DSP program counter
+// F1A114 R/W xxxxxxxx xx-xxxxx D_CTRL - DSP control/status register
+// R xxxx---- -------- (VERSION - DSP version code)
+// R/W ----x--- -------- (BUS_HOG - hog the bus!)
+// R/W -----x-- -------- (D_EXT0LAT - external interrupt 0 latch)
+// R/W ------x- -------- (D_TIM2LAT - timer 2 interrupt latch)
+// R/W -------x -------- (D_TIM1LAT - timer 1 interrupt latch)
+// R/W -------- x------- (D_I2SLAT - I2S interrupt latch)
+// R/W -------- -x------ (D_CPULAT - CPU interrupt latch)
+// R/W -------- ---x---- (SINGLE_GO - single step one instruction)
+// R/W -------- ----x--- (SINGLE_STEP - single step mode)
+// R/W -------- -----x-- (FORCEINT0 - cause interrupt 0 on GPU)
+// R/W -------- ------x- (CPUINT - send GPU interrupt to CPU)
+// R/W -------- -------x (DSPGO - enable DSP execution)
+// F1A116 R/W -------- -------x D_CTRL - upper DSP control/status register
+// R/W -------- -------x (D_EXT1LAT - external interrupt 1 latch)
+// F1A118-F1A11B W xxxxxxxx xxxxxxxx D_MOD - modulo instruction mask
+// F1A11C-F1A11F R xxxxxxxx xxxxxxxx D_REMAIN - divide unit remainder
+// F1A11C W -------- -------x D_DIVCTRL - divide unit control
+// W -------- -------x (DIV_OFFSET - 1=16.16 divide, 0=32-bit divide)
+// F1A120-F1A123 R xxxxxxxx xxxxxxxx D_MACHI - multiply & accumulate high bits
+// F1A148 W xxxxxxxx xxxxxxxx R_DAC - right transmit data
+// F1A14C W xxxxxxxx xxxxxxxx L_DAC - left transmit data
+// F1A150 W -------- xxxxxxxx SCLK - serial clock frequency
+// F1A150 R -------- ------xx SSTAT
+// R -------- ------x- (left - no description)
+// R -------- -------x (WS - word strobe status)
+// F1A154 W -------- --xxxx-x SMODE - serial mode
+// W -------- --x----- (EVERYWORD - interrupt on MSB of every word)
+// W -------- ---x---- (FALLING - interrupt on falling edge)
+// W -------- ----x--- (RISING - interrupt of rising edge)
+// W -------- -----x-- (WSEN - enable word strobes)
+// W -------- -------x (INTERNAL - enables serial clock)
+// ------------------------------------------------------------
+// F1B000-F1CFFF R/W xxxxxxxx xxxxxxxx Local DSP RAM
+// ------------------------------------------------------------
+// F1D000 R xxxxxxxx xxxxxxxx ROM_TRI - triangle wave
+// F1D200 R xxxxxxxx xxxxxxxx ROM_SINE - full sine wave
+// F1D400 R xxxxxxxx xxxxxxxx ROM_AMSINE - amplitude modulated sine wave
+// F1D600 R xxxxxxxx xxxxxxxx ROM_12W - sine wave and second order harmonic
+// F1D800 R xxxxxxxx xxxxxxxx ROM_CHIRP16 - chirp
+// F1DA00 R xxxxxxxx xxxxxxxx ROM_NTRI - traingle wave with noise
+// F1DC00 R xxxxxxxx xxxxxxxx ROM_DELTA - spike
+// F1DE00 R xxxxxxxx xxxxxxxx ROM_NOISE - white noise
+// ------------------------------------------------------------
#include "jerry.h"
#include "wavetable.h"
//#define JERRY_DEBUG
static uint8 * jerry_ram_8;
-//static uint16 *jerry_ram_16;
-static uint8 * jerry_wave_rom;
-
-//#define JERRY_CONFIG jerry_ram_16[0x4002>>1]
#define JERRY_CONFIG 0x4002
uint8 analog_x, analog_y;
static int32 jerry_timer_2_counter;
static uint32 jerry_i2s_interrupt_divide = 8;
-static int32 jerry_i2s_interrupt_timer = -1;
-static int32 jerry_i2s_interrupt_cycles_per_scanline = 0;
+static int32 jerry_i2s_interrupt_timer = -1;
+uint32 jerryI2SCycles;
+uint32 jerryIntPending;
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+//This approach is probably wrong, since the timer is continuously counting down, though
+//it might only be a problem if the # of interrupts generated is greater than 1--the M68K's
+//timeslice should be running during that phase... (The DSP needs to be aware of this!)
void jerry_i2s_exec(uint32 cycles)
{
+ extern uint16 serialMode; // From DAC.CPP
+ if (!(serialMode & 0x01)) // INTERNAL flag
+ return;
+
+ // Why is it called this? Instead of SCLK? Shouldn't this be read from DAC.CPP???
+//Yes, it should. !!! FIX !!!
jerry_i2s_interrupt_divide &= 0xFF;
if (jerry_i2s_interrupt_timer == -1)
{
- uint32 jerry_i2s_int_freq = (26591000 / 64) / (jerry_i2s_interrupt_divide + 1);
- jerry_i2s_interrupt_cycles_per_scanline = 13300000 / jerry_i2s_int_freq;
- jerry_i2s_interrupt_timer = jerry_i2s_interrupt_cycles_per_scanline;
- //fprintf(log_get(),"jerry: i2s interrupt rate set to %i hz (every %i cpu clock cycles) jerry_i2s_interrupt_divide=%i\n",jerry_i2s_int_freq,jerry_i2s_interrupt_cycles_per_scanline,jerry_i2s_interrupt_divide);
- pcm_set_sample_rate(jerry_i2s_int_freq);
+ // We don't have to divide the RISC clock rate by this--the reason is a bit
+ // convoluted. Will put explanation here later...
+// What's needed here is to find the ratio of the frequency to the number of clock cycles
+// in one second. For example, if the sample rate is 44100, we divide the clock rate by
+// this: 26590906 / 44100 = 602 cycles.
+// Which means, every 602 cycles that go by we have to generate an interrupt.
+ jerryI2SCycles = 32 * (2 * (jerry_i2s_interrupt_divide + 1));
}
+
jerry_i2s_interrupt_timer -= cycles;
- // note : commented since the sound doesn't work properly else
- if (1)//jerry_i2s_interrupt_timer<=0)
+ if (jerry_i2s_interrupt_timer <= 0)
{
- // i2s interrupt
- dsp_check_if_i2s_interrupt_needed();
- //fprintf(log_get(),"jerry_i2s_interrupt_timer=%i, generating an i2s interrupt\n",jerry_i2s_interrupt_timer);
- jerry_i2s_interrupt_timer += jerry_i2s_interrupt_cycles_per_scanline;
+ DSPSetIRQLine(DSPIRQ_SSI, ASSERT_LINE);
+ jerry_i2s_interrupt_timer += jerryI2SCycles;
+#ifdef JERRY_DEBUG
+ if (jerry_i2s_interrupt_timer < 0)
+ WriteLog("JERRY: Missed generating an interrupt (missed %u)!\n", (-jerry_i2s_interrupt_timer / jerryI2SCycles) + 1);
+#endif
}
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_reset_i2s_timer(void)
{
- //fprintf(log_get(),"i2s: reseting\n");
- jerry_i2s_interrupt_divide=8;
- jerry_i2s_interrupt_timer=-1;
+ //WriteLog("i2s: reseting\n");
+//This is really SCLK... !!! FIX !!!
+ jerry_i2s_interrupt_divide = 8;
+ jerry_i2s_interrupt_timer = -1;
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_reset_timer_1(void)
{
- if ((!jerry_timer_1_prescaler)||(!jerry_timer_1_divider))
- jerry_timer_1_counter=0;
+ if (!jerry_timer_1_prescaler || !jerry_timer_1_divider)
+ jerry_timer_1_counter = 0;
else
- jerry_timer_1_counter=(1+jerry_timer_1_prescaler)*(1+jerry_timer_1_divider);
+ jerry_timer_1_counter = (1 + jerry_timer_1_prescaler) * (1 + jerry_timer_1_divider);
// if (jerry_timer_1_counter)
-// fprintf(log_get(),"jerry: reseting timer 1 to 0x%.8x (%i)\n",jerry_timer_1_counter,jerry_timer_1_counter);
+// WriteLog("jerry: reseting timer 1 to 0x%.8x (%i)\n",jerry_timer_1_counter,jerry_timer_1_counter);
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_reset_timer_2(void)
{
- if ((!jerry_timer_2_prescaler)||(!jerry_timer_2_divider))
+ if (!jerry_timer_2_prescaler || !jerry_timer_2_divider)
{
- jerry_timer_2_counter=0;
+ jerry_timer_2_counter = 0;
return;
}
else
- jerry_timer_2_counter=((1+jerry_timer_2_prescaler)*(1+jerry_timer_2_divider));
+ jerry_timer_2_counter = ((1 + jerry_timer_2_prescaler) * (1 + jerry_timer_2_divider));
// if (jerry_timer_2_counter)
-// fprintf(log_get(),"jerry: reseting timer 2 to 0x%.8x (%i)\n",jerry_timer_2_counter,jerry_timer_2_counter);
+// WriteLog("jerry: reseting timer 2 to 0x%.8x (%i)\n",jerry_timer_2_counter,jerry_timer_2_counter);
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_pit_exec(uint32 cycles)
{
if (jerry_timer_1_counter)
- jerry_timer_1_counter-=cycles;
+ jerry_timer_1_counter -= cycles;
- if (jerry_timer_1_counter<=0)
+ if (jerry_timer_1_counter <= 0)
{
- dsp_set_irq_line(2,1);
+ DSPSetIRQLine(DSPIRQ_TIMER0, ASSERT_LINE);
jerry_reset_timer_1();
}
if (jerry_timer_2_counter)
- jerry_timer_2_counter-=cycles;
+ jerry_timer_2_counter -= cycles;
- if (jerry_timer_2_counter<=0)
+ if (jerry_timer_2_counter <= 0)
{
- dsp_set_irq_line(3,1);
+ DSPSetIRQLine(DSPIRQ_TIMER1, ASSERT_LINE);
jerry_reset_timer_2();
}
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
-void jerry_wave_rom_init(void)
-{
- memory_malloc_secure((void **)&jerry_wave_rom, 0x1000, "jerry wave rom");
- uint32 * jaguar_wave_rom_32 = (uint32 *)jerry_wave_rom;
-
-/* for (i = 0; i < 0x80; i++)
- {
- // F1D000 = triangle wave
- jaguar_wave_rom_32[0x000 + i] = ((i <= 0x40) ? i : 0x80 - i) * 32767 / 0x40;
-
- // F1D200 = full sine wave
- jaguar_wave_rom_32[0x080 + i] = (int)(32767. * sin(2.0 * 3.1415927 * (double)i / (double)0x80));
-
- // F1D400 = amplitude modulated sine wave?
- jaguar_wave_rom_32[0x100 + i] = (int)(32767. * sin(2.0 * 3.1415927 * (double)i / (double)0x80));
- // F1D600 = sine wave and second order harmonic
- jaguar_wave_rom_32[0x180 + i] = (int)(32767. * sin(2.0 * 3.1415927 * (double)i / (double)0x80));
-
- // F1D800 = chirp (sine wave of increasing frequency)
- jaguar_wave_rom_32[0x200 + i] = (int)(32767. * sin(2.0 * 3.1415927 * (double)i / (double)0x80));
-
- // F1DA00 = traingle wave with noise
- jaguar_wave_rom_32[0x280 + i] = jaguar_wave_rom_32[0x000 + i] * (rand() % 32768) / 32768;
-
- // F1DC00 = spike
- jaguar_wave_rom_32[0x300 + i] = (i == 0x40) ? 32767 : 0;
-
- // F1DE00 = white noise
- jaguar_wave_rom_32[0x380 + i] = rand() % 32768;
- }
- */
- // use real wave table dump
-// Looks like this WT dump is in the wrong endian...
- memcpy(jerry_wave_rom, wave_table, 0x1000);
-
- // reverse byte ordering
-// Actually, this does nothing...
- for(int i=0; i<0x400; i++)
- {
- uint32 data = jaguar_wave_rom_32[i];
- data = ((data&0xff000000)>>24)|((data&0x0000ff00)<<8)|
- ((data&0x00ff0000)>>8) |((data&0x000000ff)<<24);
- }
-
- // copy it to dsp ram
- memcpy(&jerry_ram_8[0xD000], jerry_wave_rom, 0x1000);
-}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
void jerry_init(void)
{
- //fprintf(log_get(),"jerry_init()\n");
clock_init();
anajoy_init();
joystick_init();
- eeprom_init();
- memory_malloc_secure((void **)&jerry_ram_8, 0x10000, "jerry ram");
-// jerry_ram_16 = (uint16 *)jerry_ram_8;
- jerry_wave_rom_init();
+ DACInit();
+//This should be handled with the cart initialization...
+// eeprom_init();
+ memory_malloc_secure((void **)&jerry_ram_8, 0x10000, "JERRY RAM/ROM");
+ memcpy(&jerry_ram_8[0xD000], wave_table, 0x1000);
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_reset(void)
{
- //fprintf(log_get(),"jerry_reset()\n");
clock_reset();
anajoy_reset();
joystick_reset();
eeprom_reset();
jerry_reset_i2s_timer();
+ DACReset();
- memset(jerry_ram_8, 0x00, 0x10000);
- jerry_ram_8[JERRY_CONFIG+1] |= 0x10; // NTSC (bit 4)
+ memset(jerry_ram_8, 0x00, 0xD000); // Don't clear out the Wavetable ROM...!
jerry_timer_1_prescaler = 0xFFFF;
jerry_timer_2_prescaler = 0xFFFF;
jerry_timer_1_divider = 0xFFFF;
jerry_timer_2_divider = 0xFFFF;
jerry_timer_1_counter = 0;
jerry_timer_2_counter = 0;
-
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
-//
-//
-//////////////////////////////////////////////////////////////////////////////
+
void jerry_done(void)
{
- //fprintf(log_get(),"jerry_done()\n");
+ WriteLog("JERRY: M68K Interrupt control ($F10020) = %04X\n", GET16(jerry_ram_8, 0x20));
memory_free(jerry_ram_8);
clock_done();
anajoy_done();
joystick_done();
+ DACDone();
eeprom_done();
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
+
+bool JERRYIRQEnabled(int irq)
+{
+ // Read the word @ $F10020
+ return jerry_ram_8[0x21] & (1 << irq);
+}
+
+void JERRYSetPendingIRQ(int irq)
+{
+ // This is the shadow of INT (it's a split RO/WO register)
+ jerryIntPending |= (1 << irq);
+}
+
//
+// JERRY byte access (read)
//
-//////////////////////////////////////////////////////////////////////////////
-unsigned jerry_byte_read(unsigned int offset)
+uint8 JERRYReadByte(uint32 offset, uint32 who/*=UNKNOWN*/)
{
#ifdef JERRY_DEBUG
- fprintf(log_get(),"jerry: reading byte at 0x%.6x\n",offset);
+ WriteLog("JERRY: Reading byte at %06X\n", offset);
#endif
- if ((offset >= dsp_control_ram_base) && (offset < dsp_control_ram_base+0x20))
- return dsp_byte_read(offset);
-
- if ((offset >= dsp_work_ram_base) && (offset < dsp_work_ram_base+0x2000))
- return dsp_byte_read(offset);
-
- if ((offset >= 0xF10000) && (offset <= 0xF10007))
+ if ((offset >= DSP_CONTROL_RAM_BASE) && (offset < DSP_CONTROL_RAM_BASE+0x20))
+ return DSPReadByte(offset, who);
+ else if ((offset >= DSP_WORK_RAM_BASE) && (offset < DSP_WORK_RAM_BASE+0x2000))
+ return DSPReadByte(offset, who);
+ else if (offset >= 0xF10000 && offset <= 0xF10007)
{
switch(offset & 0x07)
{
- case 0: return(jerry_timer_1_prescaler>>8);
- case 1: return(jerry_timer_1_prescaler&0xff);
- case 2: return(jerry_timer_1_divider>>8);
- case 3: return(jerry_timer_1_divider&0xff);
- case 4: return(jerry_timer_2_prescaler>>8);
- case 5: return(jerry_timer_2_prescaler&0xff);
- case 6: return(jerry_timer_2_divider>>8);
- case 7: return(jerry_timer_2_divider&0xff);
+ case 0:
+ return jerry_timer_1_prescaler >> 8;
+ case 1:
+ return jerry_timer_1_prescaler & 0xFF;
+ case 2:
+ return jerry_timer_1_divider >> 8;
+ case 3:
+ return jerry_timer_1_divider & 0xFF;
+ case 4:
+ return jerry_timer_2_prescaler >> 8;
+ case 5:
+ return jerry_timer_2_prescaler & 0xFF;
+ case 6:
+ return jerry_timer_2_divider >> 8;
+ case 7:
+ return jerry_timer_2_divider & 0xFF;
}
}
-
- if ((offset>=0xf10010)&&(offset<0xf10016))
- return(clock_byte_read(offset));
-
- if ((offset>=0xf17c00)&&(offset<0xf17c02))
- return(anajoy_byte_read(offset));
-
- if ((offset>=0xf14000)&&(offset<=0xf14003))
+ else if (offset >= 0xF10010 && offset <= 0xF10015)
+ return clock_byte_read(offset);
+ else if (offset >= 0xF17C00 && offset <= 0xF17C01)
+ return anajoy_byte_read(offset);
+ else if (offset >= 0xF14000 && offset <= 0xF14003)
{
- return(joystick_byte_read(offset)|eeprom_byte_read(offset));
+ return joystick_byte_read(offset) | eeprom_byte_read(offset);
}
-
- if ((offset >= 0xF14000) && (offset <= 0xF1A0FF))
- return(eeprom_byte_read(offset));
+ else if (offset >= 0xF14000 && offset <= 0xF1A0FF)
+ return eeprom_byte_read(offset);
return jerry_ram_8[offset & 0xFFFF];
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
+
//
+// JERRY word access (read)
//
-//////////////////////////////////////////////////////////////////////////////
-unsigned jerry_word_read(unsigned int offset)
+uint16 JERRYReadWord(uint32 offset, uint32 who/*=UNKNOWN*/)
{
#ifdef JERRY_DEBUG
- fprintf(log_get(),"jerry: reading word at 0x%.6x\n",offset);
+ WriteLog("JERRY: Reading word at %06X\n", offset);
#endif
- if ((offset>=dsp_control_ram_base)&&(offset<dsp_control_ram_base+0x20))
- return(dsp_word_read(offset));
- if ((offset>=dsp_work_ram_base)&&(offset<dsp_work_ram_base+0x2000))
- return(dsp_word_read(offset));
-
- if ((offset>=0xf10000)&&(offset<=0xf10007))
+ if ((offset >= DSP_CONTROL_RAM_BASE) && (offset < DSP_CONTROL_RAM_BASE+0x20))
+ return DSPReadWord(offset, who);
+ else if (offset >= DSP_WORK_RAM_BASE && offset <= DSP_WORK_RAM_BASE + 0x1FFF)
+ return DSPReadWord(offset, who);
+ else if ((offset >= 0xF10000) && (offset <= 0xF10007))
{
- switch(offset&0x07)
+ switch(offset & 0x07)
{
- case 0: return(jerry_timer_1_prescaler);
- case 2: return(jerry_timer_1_divider);
- case 4: return(jerry_timer_2_prescaler);
- case 6: return(jerry_timer_2_divider);
+ case 0:
+ return jerry_timer_1_prescaler;
+ case 2:
+ return jerry_timer_1_divider;
+ case 4:
+ return jerry_timer_2_prescaler;
+ case 6:
+ return jerry_timer_2_divider;
}
+ // Unaligned word reads???
}
-
- if ((offset>=0xf10010)&&(offset<0xf10016))
- return(clock_word_read(offset));
-
- if (offset==0xF10020)
- return(0x00);
-
- if ((offset>=0xf17c00)&&(offset<0xf17c02))
- return(anajoy_word_read(offset));
-
- if (offset==0xf14000)
+ else if ((offset >= 0xF10010) && (offset <= 0xF10015))
+ return clock_word_read(offset);
+ else if (offset == 0xF10020)
+ return jerryIntPending;
+ else if ((offset >= 0xF17C00) && (offset <= 0xF17C01))
+ return anajoy_word_read(offset);
+ else if (offset == 0xF14000)
{
- uint16 dta=(joystick_word_read(offset)&0xfffe)|eeprom_word_read(offset);
- //fprintf(log_get(),"reading 0x%.4x from 0xf14000\n");
- return(dta);
+ //WriteLog("reading 0x%.4x from 0xf14000\n");
+ return (joystick_word_read(offset) & 0xFFFE) | eeprom_word_read(offset);
}
- if ((offset>=0xf14002)&&(offset<0xf14003))
- return(joystick_word_read(offset));
-
- if ((offset>=0xf14000)&&(offset<=0xF1A0FF))
- return(eeprom_word_read(offset));
-
+ else if ((offset >= 0xF14002) && (offset < 0xF14003))
+ return joystick_word_read(offset);
+ else if ((offset >= 0xF14000) && (offset <= 0xF1A0FF))
+ return eeprom_word_read(offset);
+/*if (offset >= 0xF1D000)
+ WriteLog("JERRY: Reading word at %08X [%04X]...\n", offset, ((uint16)jerry_ram_8[(offset+0)&0xFFFF] << 8) | jerry_ram_8[(offset+1)&0xFFFF]);//*/
- offset&=0xffff;
- if (offset==0x4002)
- return(0xffff);
-
-
- uint16 data=jerry_ram_8[offset+0];
- data<<=8;
- data|=jerry_ram_8[offset+1];
- return(data);
+ offset &= 0xFFFF; // Prevent crashing...!
+ return ((uint16)jerry_ram_8[offset+0] << 8) | jerry_ram_8[offset+1];
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
+
//
+// JERRY byte access (write)
//
-//////////////////////////////////////////////////////////////////////////////
-void jerry_byte_write(unsigned offset, unsigned data)
+void JERRYWriteByte(uint32 offset, uint8 data, uint32 who/*=UNKNOWN*/)
{
#ifdef JERRY_DEBUG
- fprintf(log_get(),"jerry: writing byte %.2x at 0x%.6x\n",data,offset);
+ WriteLog("jerry: writing byte %.2x at 0x%.6x\n",data,offset);
#endif
- if ((offset>=dsp_control_ram_base)&&(offset<dsp_control_ram_base+0x20))
+ if ((offset >= DSP_CONTROL_RAM_BASE) && (offset < DSP_CONTROL_RAM_BASE+0x20))
{
- dsp_byte_write(offset,data);
+ DSPWriteByte(offset, data, who);
return;
}
- if ((offset>=dsp_work_ram_base)&&(offset<dsp_work_ram_base+0x2000))
+ else if ((offset >= DSP_WORK_RAM_BASE) && (offset < DSP_WORK_RAM_BASE+0x2000))
{
- dsp_byte_write(offset,data);
+ DSPWriteByte(offset, data, who);
return;
}
-
- if ((offset>=0xf1a152)&&(offset<0xf1a154))
+ // SCLK ($F1A150--8 bits wide)
+ else if ((offset >= 0xF1A152) && (offset <= 0xF1A153))
{
-// fprintf(log_get(),"i2s: writing 0x%.2x to SCLK\n",data);
- if ((offset&0x03)==2)
- jerry_i2s_interrupt_divide=(jerry_i2s_interrupt_divide&0x00ff)|(((uint32)data)<<8);
+// WriteLog("JERRY: Writing %02X to SCLK...\n", data);
+ if ((offset & 0x03) == 2)
+ jerry_i2s_interrupt_divide = (jerry_i2s_interrupt_divide & 0x00FF) | ((uint32)data << 8);
else
- jerry_i2s_interrupt_divide=(jerry_i2s_interrupt_divide&0xff00)|((uint32)data);
+ jerry_i2s_interrupt_divide = (jerry_i2s_interrupt_divide & 0xFF00) | (uint32)data;
- jerry_i2s_interrupt_timer=-1;
+ jerry_i2s_interrupt_timer = -1;
jerry_i2s_exec(0);
+// return;
+ }
+ // LTXD/RTXD/SCLK/SMODE $F1A148/4C/50/54 (really 16-bit registers...)
+ else if (offset >= 0xF1A148 && offset <= 0xF1A157)
+ {
+ DACWriteByte(offset, data);
+ return;
}
- if ((offset>=0xf10000)&&(offset<=0xf10007))
+ else if (offset >= 0xF10000 && offset <= 0xF10007)
{
- switch(offset&0x07)
+ switch (offset & 0x07)
{
- case 0: { jerry_timer_1_prescaler=(jerry_timer_1_prescaler&0x00ff)|(data<<8); jerry_reset_timer_1(); return; }
- case 1: { jerry_timer_1_prescaler=(jerry_timer_1_prescaler&0xff00)|(data); jerry_reset_timer_1(); return; }
+ case 0:
+ jerry_timer_1_prescaler = (jerry_timer_1_prescaler & 0x00FF) | (data << 8);
+ jerry_reset_timer_1();
+ break;
+ case 1:
+ jerry_timer_1_prescaler = (jerry_timer_1_prescaler & 0xFF00) | (data);
+ jerry_reset_timer_1();
+ break;
case 2: { jerry_timer_1_divider=(jerry_timer_1_divider&0x00ff)|(data<<8); jerry_reset_timer_1(); return; }
case 3: { jerry_timer_1_divider=(jerry_timer_1_divider&0xff00)|(data); jerry_reset_timer_1(); return; }
case 4: { jerry_timer_2_prescaler=(jerry_timer_2_prescaler&0x00ff)|(data<<8); jerry_reset_timer_2(); return; }
case 6: { jerry_timer_2_divider=(jerry_timer_2_divider&0x00ff)|(data<<8); jerry_reset_timer_2(); return; }
case 7: { jerry_timer_2_divider=(jerry_timer_2_divider&0xff00)|(data); jerry_reset_timer_2(); return; }
}
+ return;
}
-
-
- if ((offset>=0xf10010)&&(offset<0xf10016))
+ else if ((offset >= 0xF10010) && (offset <= 0xF10015))
{
- clock_byte_write(offset,data);
+ clock_byte_write(offset, data);
return;
}
- if ((offset>=0xf17c00)&&(offset<0xf17c02))
+ else if ((offset >= 0xF17C00) && (offset <= 0xF17C01))
{
- anajoy_byte_write(offset,data);
+ anajoy_byte_write(offset, data);
return;
}
- if ((offset>=0xf14000)&&(offset<0xf14003))
+ else if ((offset >= 0xF14000) && (offset <= 0xF14003))
{
- joystick_byte_write(offset,data);
- eeprom_byte_write(offset,data);
+ joystick_byte_write(offset, data);
+ eeprom_byte_write(offset, data);
return;
}
- if ((offset>=0xf14000)&&(offset<=0xF1A0FF))
+ else if ((offset >= 0xF14000) && (offset <= 0xF1A0FF))
{
- eeprom_byte_write(offset,data);
+ eeprom_byte_write(offset, data);
return;
}
- offset&=0xffff;
- jerry_ram_8[offset]=data;
+
+//Need to protect write attempts to Wavetable ROM (F1D000-FFF)
+ if (offset >= 0xF1D000 && offset <= 0xF1DFFF)
+ return;
+
+ jerry_ram_8[offset & 0xFFFF] = data;
}
-//////////////////////////////////////////////////////////////////////////////
-//
-//////////////////////////////////////////////////////////////////////////////
-//
-//
-//
-//
+
//
+// JERRY word access (write)
//
-//////////////////////////////////////////////////////////////////////////////
-void jerry_word_write(unsigned offset, unsigned data)
+void JERRYWriteWord(uint32 offset, uint16 data, uint32 who/*=UNKNOWN*/)
{
#ifdef JERRY_DEBUG
- fprintf(log_get(), "JERRY: Writing word %04X at %06X\n", data, offset);
+ WriteLog( "JERRY: Writing word %04X at %06X\n", data, offset);
#endif
- if ((offset >= dsp_control_ram_base) && (offset < dsp_control_ram_base+0x20))
+ if ((offset >= DSP_CONTROL_RAM_BASE) && (offset < DSP_CONTROL_RAM_BASE+0x20))
{
- dsp_word_write(offset, data);
+ DSPWriteWord(offset, data, who);
return;
}
- if ((offset >=dsp_work_ram_base) && (offset < dsp_work_ram_base+0x2000))
+ else if ((offset >= DSP_WORK_RAM_BASE) && (offset < DSP_WORK_RAM_BASE+0x2000))
{
- dsp_word_write(offset, data);
+ DSPWriteWord(offset, data, who);
return;
}
- if (offset == 0xF1A152)
+ else if (offset == 0xF1A152) // Bottom half of SCLK ($F1A150)
{
-// fprintf(log_get(),"i2s: writing 0x%.4x to SCLK\n",data);
- jerry_i2s_interrupt_divide = data & 0xFF;
+ WriteLog("JERRY: Writing %04X to SCLK (by %s)...\n", data, whoName[who]);
+ jerry_i2s_interrupt_divide = (uint8)data;
jerry_i2s_interrupt_timer = -1;
jerry_i2s_exec(0);
- }
- if ((offset >= 0xF10000) && (offset <= 0xF10007))
+ DACWriteWord(offset, data);
+ return;
+ }
+ // LTXD/RTXD/SCLK/SMODE $F1A148/4C/50/54 (really 16-bit registers...)
+ else if (offset >= 0xF1A148 && offset <= 0xF1A156)
+ {
+ DACWriteWord(offset, data);
+ return;
+ }
+ else if ((offset >= 0xF10000) && (offset <= 0xF10007))
{
switch(offset & 0x07)
{
- case 0: { jerry_timer_1_prescaler=data; jerry_reset_timer_1(); return; }
- case 2: { jerry_timer_1_divider=data; jerry_reset_timer_1(); return; }
- case 4: { jerry_timer_2_prescaler=data; jerry_reset_timer_2(); return; }
- case 6: { jerry_timer_2_divider=data; jerry_reset_timer_2(); return; }
+ case 0:
+ jerry_timer_1_prescaler = data;
+ jerry_reset_timer_1();
+ break;
+ case 2:
+ jerry_timer_1_divider = data;
+ jerry_reset_timer_1();
+ break;
+ case 4:
+ jerry_timer_2_prescaler = data;
+ jerry_reset_timer_2();
+ break;
+ case 6:
+ jerry_timer_2_divider = data;
+ jerry_reset_timer_2();
}
+ // Need to handle (unaligned) cases???
+ return;
}
-
- if ((offset >= 0xF1A148) && (offset < 0xF1A150))
- {
- pcm_word_write(offset-0xF1A148, data);
- return;
- }
-
- if ((offset >= 0xF10010) && (offset < 0xF10016))
+ else if ((offset >= 0xF10010) && (offset < 0xF10016))
{
clock_word_write(offset, data);
return;
}
- if ((offset >= 0xf17C00) && (offset < 0xF17C02))
+ // JERRY -> 68K interrupt enables/latches (need to be handled!)
+ else if (offset >= 0xF10020 && offset <= 0xF10022)
+ {
+ }
+ else if ((offset >= 0xF17C00) && (offset < 0xF17C02))
{
+//I think this was removed from the Jaguar. If so, then we don't need this...!
anajoy_word_write(offset, data);
return;
}
- if ((offset >= 0xF14000) && (offset < 0xF14003))
+ else if ((offset >= 0xF14000) && (offset < 0xF14003))
{
joystick_word_write(offset, data);
eeprom_word_write(offset, data);
return;
}
- if ((offset >= 0xF14000) && (offset <= 0xF1A0FF))
+ else if ((offset >= 0xF14000) && (offset <= 0xF1A0FF))
{
- eeprom_word_write(offset,data);
+ eeprom_word_write(offset, data);
return;
}
+//Need to protect write attempts to Wavetable ROM (F1D000-FFF)
+ if (offset >= 0xF1D000 && offset <= 0xF1DFFF)
+ return;
+
jerry_ram_8[(offset+0) & 0xFFFF] = (data >> 8) & 0xFF;
jerry_ram_8[(offset+1) & 0xFFFF] = data & 0xFF;
-
}